Cosmos
Book Author | |
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Published | January 1, 1980 |
Pages | 365 |
One small step toward understanding the greatness of the universe
What’s it about?
Cosmos (1980) is a milestone in popular science. It shows us the basic concepts behind our understanding of the universe, what the planets and the stars look like and how our comprehension of them has changed and evolved.
About the author
Carl Sagan was an American astronomer, author and famous popularizer of science. He co-wrote and narrated the television series Cosmos: A Personal Voyage, which was based on his best-selling book. It won him several awards, including an Emmy for Outstanding Individual Achievement.
Basic Key Ideas
Sometimes the drama of life can be overwhelming. Forgot to pick up your sister from the airport? Flunked another exam? At times like these, it may seem that your life is all-consuming and has taken over every iota of the earth’s energy. But, of course, there are billions of other people in the world. And as for the earth itself, well, that is just the smallest bit of grit in an ever-expanding universe. What have you got to worry about?
Carl Sagan’s talents lay in making the difficult relatable. And in many ways, nothing is more massive than the Cosmos. Learning about the universe isn’t always about difficult math. It’s as much a history lesson as a science lesson. Following on from Sagan’s lead, these blinks take you on a journey through humanity’s interest in the universe and space from prehistoric times through to the greatest voyages of space exploration in the twentieth century.
In this pack, you’ll learn
- what alien life-forms might think of us;
- which Greek was no flat-earther; and
- about one of Einstein’s famous thought experiments.
The history of humankind has long been confined to earth. To us, it is everything, quite literally our world. But compared to the universe as a whole, the earth is really just a speck within a speck of dust. That’s because the size of the universe, or the Cosmos, is almost beyond comprehension.
In fact, it’s so big that we’ve had to create a special unit of measurement based on the speed of light.
Light is the fastest thing in the universe: in just one second it travels 186,000 miles or 300,000 km. That, in relatable terms, is equivalent to seven times around the earth.
Based on that, when scientists talk about the Cosmos, they use light-years. That’s the distance that light travels in a whole year. To put a figure on it, about 6 trillion miles, or 10 trillion km!
If that wasn’t already remarkable enough, consider that the Cosmos has contained within it roughly a hundred billion, or 1011, galaxies. And within each galaxy, there are roughly 1011 stars and 1011 planets.
If you do the math, you’ll realize that our planet is one of 1022 planets in the Cosmos. Terrifyingly insignificant.
Earth’s basic physical properties have long been known to humans. Around 2,000 years ago, scientists were already investigating its nature. They even calculated that the earth’s landmass was neither infinite nor flat.
In the third century BCE, Eratosthenes, the director of the famous great Library of Alexandria in Egypt, worked out that the earth was a sphere.
While reading a papyrus scroll one day, Eratosthenes learned that in Syene, modern Aswan, near the Nile, sticks cast no shadow at midday. This implied that at noon in Syene the sun was directly overhead.
So Eratosthenes experimented. He placed a stick in the ground in Alexandria and observed that at midday there was a shadow in the city.
From this, he concluded that the earth could not be flat. It had to be curved. If the land was flat, either both sticks would simultaneously have no shadow, or they would be at the same angle to the sun and therefore would have the same length of shadow.
He even managed to use the difference in shadow lengths to calculate the circumference of the earth correctly. But he had to hire a man to pace out the distance between Alexandria and Syene (a walk of around 1,000 km) to get the final measurement he needed for the sum!
This discovery was critical. Based on this knowledge, ambitious explorers set sail on little boats. How far they got, we may never know. But the spirit of exploration is still spurred on by science to this day. What are satellites but ships sailing through space?
From before the dawn of history, humans have looked up into the heavens and tried to make sense of those little dots that twinkle away in the night sky.
But they didn’t just look at them; they also realized they could use them.
Some 40,000 generations ago, our nomadic ancestors fixed the dates of annual meetings with other tribes in other lands by looking at the position of the stars.
They also used the stars to calculate the rhythm of the seasons to know when certain fruits would be ready to pick, and when antelope and buffalo would migrate.
This is all possible because of the regular and predictable movement of heavenly bodies.
In fact, if you trace the movement of the planets over time, you’ll see they’re doing a kind of loop-the-loop across the sky.
This observation led Ptolemy, who worked in the Library of Alexandria in the second century CE, to posit a theory. To Ptolemy, the earth was the center of the universe and the stars and planets revolved around it.
It was a theory that stood for centuries. Only in 1543 did Nicolaus Copernicus radically theorize that the earth, and the other planets, revolved around the sun.
Now the sun was seen as the center of the universe.
The model was further refined around 60 years later. German-born astronomer Johannes Kepler got his hands on the impressively comprehensive data compiled by the late Tycho Brahe, a Danish nobleman and observational astronomer.
Based on these datasets, Kepler calculated that the planets’ orbits around the sun were not circular, as has been previously thought, but were in fact elliptical. This formed the first of his three laws of planetary motion, and these remain in use in astrophysics to this day.
Kepler also had a very interesting theory. He argued that a force that he called “magnetism” impacted on bodies at a distance. This would explain why planets speed up when they came closest to the sun. If it sounds sort of familiar, it’s because Kepler essentially anticipated Isaac Newton’s theory of universal gravitation by about half a century.
The old saying goes “Men are from Mars, and women are from Venus.” It’s based on the Roman idea that Venus was the goddess of love, while Mars was the god of war. It’s a nice expression, but the physics is quite another matter.
There’s no way around it. Venus is basically our solar system’s version of hell. As Venus is 60 million km closer to the sun than earth, it gets mighty hot. Surface temperatures can reach levels of 900°F or 480°C.
It gets worse. We can work out what the planet’s atmosphere is composed of. Astronomical spectroscopy is used to analyze the light reflected off Venus. It shows that the atmosphere is, in fact, 96 percent carbon dioxide. And up above its surface, the clouds are made of concentrated sulfuric acid. These create the greenhouse effect that helps keep the planet hot.
Venus certainly doesn’t sound like the kind of place to spend a romantic holiday.
Things are a little different on Mars. It wouldn’t make a good honeymoon spot either, but at least it’s a bit more earth-like. Mars is the closest planet to earth, and in some ways is pretty similar. It has polar ice caps, white clouds, dust storms. Even its days are 24 hours long.
Those similarities may explain why we think of aliens as being “Martians.” The Martian myth can be traced back to Bostonian Percival Lowell, the founder of the Lowell Observatory in Flagstaff Arizona in 1894.
Lowell convinced himself that there were indications of water canals on the surface of Mars. He thought that these must have been dug by intelligent life on the planet.
Even though his conviction was, of course, later proven false, the myth still persisted in popular culture.
That said, it’s not a crazy idea that we humans could one day live on Mars. The planet is colder than the earth; temperatures range from 0°C to -80°C or 32°F to -112°F. But, that’s really not so different from the Antarctic, where humans can and do survive.
The biggest challenge for humans living on Mars would be the sourcing of water. There are no open bodies of water on Mars, and there is no water in its atmosphere. Things get more complicated still because the atmospheric pressure is so low, water would boil away a lot faster than it does on earth.
That said, if we could melt Mars’s polar ice caps to fill constructed water canals like the ones Lowell thought he saw, then maybe one day we humans might be able to call ourselves Martians.
All in all, if there are going to be real Martians one day, it might just be us humans. But this doesn’t stop us asking related questions: is there life on other planets or in other galaxies?
We can’t be certain, but there’s one thing we can be reasonably secure about. Extraterrestrials would definitely look very different from us.
Just think of all the variety of life on earth. From single-cell bacteria to whales, insects and humans, evolution has created a rich cornucopia. It’s been a long and slow process full of random mutations and, critically, dependent upon conditions on earth.
This means there’s no reason to think that lifeforms on another planet would look anything like those on earth. After all, this other planet would have completely different conditions and a different evolutionary history.
But that doesn’t mean we can’t try to guess what this other life might look like. What about Jupiter? Well, Jupiter is an enormous gas planet with plenty of hydrogen and helium in its atmosphere.
If there were lifeforms there, they might exist as giant gas balloons, perhaps even kilometers across. They’d probably propel themselves by expelling gusts of gas, and perhaps make their own food through a process similar to plant photosynthesis here on earth.
All that said, if we’re going to communicate with extraterrestrials, it’s unlikely our first point of contact will be in person. Most likely they’d contact us first through radio waves. That’s because radio is a cheap, fast and simple way to communicate across large distances.
Any advanced extraterrestrial civilization will know that even a civilization as “simple” as our own would probably have worked out the basics of radio and would attempt to use it to receive transmissions from space. So that’s probably what they would try sending to us.
But what kind of message they would send? Something like a sequence of prime numbers might work well. That’s because the ideal message should indicate clearly and concisely that it is deliberate and being sent by an intelligent lifeform.
And what about us? Could we make physical contact with life on other planets? Well, it’s theoretically possible, but politics makes it unlikely. In 1958, Project Orion was initiated. The idea was to create an interstellar aircraft that would be propelled by massive amounts of energy. This energy would be produced by small atomic explosions outside the aircraft.
But it wasn’t to be. In 1963, the United States and the Soviet Union signed a treaty which forbade “the detonation of nuclear weapons in space.” And just like that, the possibility of an Orion-type starship reaching the stars was lost.
For most people, modern science has some sort of association with the Enlightenment or with the likes of Copernicus and da Vinci, who were themselves products of the sixteenth-century Renaissance.
But in fact, modern science has much deeper roots. The Ionians of Greece were its forefathers.
Ionia was a region in the eastern Mediterranean: what we might think of now as the eastern Greek islands and the western coast of Turkey. In ancient times, it stood at the crossroads of civilization. Not only was Ionia a center of trade, but the region was also influenced by Egyptians, Babylonians and other mighty civilizations.
Each of these civilizations had its gods, who were thought to reign over the territory.
This left the Ionians a little confused. Who were they to worship, the Greek god Zeus or the Babylonian Marduk? The conclusion they came to was startling. They determined that principles of physics and laws of nature governed the world instead.
The Ionians started experimenting and so ushered in a scientific revolution. Perhaps most famously, Democritus invented the concept of the atom in around 430 BCE. It’s a Greek word that means “uncuttable.” He argued that when you cut an apple, your knife is actually passing through the empty spaces between atoms. Consequently, he determined that every object could be thought of as comprising atoms and empty spaces.
Sadly, however, experimental Ionian approaches and learning were suppressed for centuries. We can blame the Greek Pythagoras for this.
Pythagoras and his disciples believed that the world, being perfect and divine, obeyed set geometrical laws. All they needed was pure thought and nothing else. Experimentation had no place in this academic mind-set.
Critically, the greatest philosophers of the classical world, Plato and Aristotle among them, were profoundly influenced by Pythagoras’ ideas.
In the fifth to fourth centuries BCE, they started to make the argument that experimenting was no different from manual work in the fields. It was, therefore, work only suitable for slaves. Pure intellectual work should, conversely, be theoretical.
When Christianity grew dominant, it also took the Pythagorean notion of a perfect divine world. Consequently, scientific endeavors that might have led to new doctrine-threatening discoveries were suppressed.
This censorship cast a long shadow. It took until the sixteenth century before the scientific method of observation and experimentation was revived.
Even based on what we can see with our eyes and with telescopes, it’s clear that the universe is a wondrous and mysterious place. Exploding stars, cosmic dust, comets and the richness of planetary colors are incredible in their own right. But what’s even more amazing is that there’s much more about the Cosmos that we can explain but can’t see.
The classic case is the speed of light. What’s incredible is not only its speed but also the fact that this speed is a constant and nothing can exceed it.
Albert Einstein worked out these properties of light in the early twentieth century through a series of what he called Gedankenexperimente, German for “thought experiments.”
Here’s an example. Imagine you’re in a car, about to go over a railroad crossing. A train is on the tracks at a right angle to you and is heading for the same crossing. As you approach the crossing, you realize that you will reach it at exactly the same time as the train. So you slow down just in time to avoid the crash.
Imagine instead that a friend of yours is on the other side of the railroad crossing from you. He’s further down the road you’re on and is watching you drive straight at him.
Now for the thought experiment: what if both you and the train were traveling close to the speed of light?
Your friend will see you thanks to light reflected off your car. If the speed of light was changeable, the light would reach you at the speed of light + the speed of the car. The light reflected off the train – which isn’t traveling towards you – would only arrive at the speed of light. In other words, your friend would see you reach the crossing before the train. How can your friend and you experience the same event differently?
Einstein realized counterintuitive situations like these could only be avoided if the following rules were followed. Firstly, light always travels at the same speed, no matter who’s observing it. Secondly, nothing can travel faster than the speed of light.
Ever since Eratosthenes discovered that the earth was curved, explorers and travelers have been inspired by science to travel to discover new realms.
Nothing symbolizes our sense of discovery better than the voyages of the unmanned spacecraft that are traveling through our solar system and out into space.
NASA launched Voyagers 1 and 2 into space in September and August 1977 respectively. The two spacecraft were cleverly designed: they are made of millions of parts assembled redundantly. That means that if one part fails, another can fulfill its role.
For instance, each has three different kinds of computer, and each computer is itself duplicated.
Their power sources are intended to last. It’s kind of like having “a small nuclear power plant” on board. Energy is produced by the decay “of a pellet of plutonium.”
Both craft are supplying us with plenty of data too, including photographs that are sent back to earth using radio. Linda Morabito of the Voyager team was able to use some of these pictures in 1979 to discover an active volcano on Io, the innermost moon of Jupiter.
The Voyager crafts don’t just send us signals; they also carry information about the best aspects of humanity. The scientists decided upon this very carefully.
They were aware that should extraterrestrial life-forms intercept signals from earth, they would no doubt get very confused indeed. They would most probably pick up the signals from radio and television broadcasts. Their picture of earth would be a mix of advertisements for cars and detergents, blended with bursts of official messages sent in times of crisis and war. What would they think of us?
Now, there’s nothing we can do about those signals: they’ve already been sent.
However, the Voyager team decided to attach to each craft a gold-plated copper phonograph with a cartridge and stylus. On the aluminum record sleeves there were even instructions on how to play the records. The discs were filled with recordings on what NASA thought was unique and interesting about earth. They included information about the cerebral cortex and limbic systems in our brains, as well as greetings in 60 human languages. There was an hour of music from cultures all around the globe, as well as sounds from nature and modern technologies.
It’s a pretty broad selection of material. Perhaps the extraterrestrials who find it will admire our achievements. Or maybe they just won’t understand. At least we can say we tried.
The key message in these blinks:
The Cosmos is a vast entity almost beyond understanding, but we do know it is filled with amazing and wonderful things. Over many centuries and thanks to much scientific research, we have learned that our earth is just one spot in the immense Cosmos. We now know our place, but astrophysics allow us to explore it bit by bit.
Suggested further reading: The Demon-Haunted World by Carl Sagan
The Demon-Haunted World (1995) helps the reader distinguish between dangerous pseudoscience and real, hard science by exploring the critical-thinking tools scientists use to make their discoveries. The author argues for science’s place in education and popular culture, and offers his advice on how we can incorporate more critical thought into our society.
SECOND REVIEW FROM SHORTFORM
About Book
What’s out there in the vast reaches of space? Are we alone in the universe? Renowned astronomer Carl Sagan offers some insight into these questions and many more in his widely acclaimed book, Cosmos.
Sagan is a Pulitzer Prize-winning author and perhaps the greatest astronomer of our age. In this book, he provides a comprehensive description of the science, philosophy, and history of astronomical discovery, from ancient Ionia to the time of the book’s publication in 1980.
In this guide, we’ll delve into Sagan’s theories about the possibility of interstellar travel, the search for extraterrestrial life, and man’s quest for understanding the mysteries of the universe. As we go along, we’ll update the information with the most recent scientific discoveries and provide perspectives from other experts in related fields.
1-Page Summary
Cosmos is astronomer Carl Sagan’s exploration of the universe. In this book, Sagan gives a comprehensive description of the science, philosophy, and history of astronomical discovery, from ancient Ionia to the time of the book’s publication in 1980. He discusses some of the obstacles posed by religious belief and institutions to scientific inquiry throughout history, and he celebrates the victories of the scientific endeavor. Although much research has been done in astronomy since the publication of Cosmos, the book remains timeless in the sense of wonder and awe it evokes. Sagan provides us with food for thought on some of the biggest questions pondered by humanity—questions about our place and significance in the vast universe.
Sagan was an American astronomer who spent most of his prolific career in Cornell University’s Laboratory for Planetary Studies. His 1977 book The Dragons of Eden, about the evolution of human intelligence, won a Pulitzer Prize. In the 1980s Sagan became a popular science writer and public figure, due largely to the success of Cosmos and the accompanying television show of the same name. His popularity continued following the publication of his 1985 science fiction novel Contact, which was made into a movie. Sagan died in 1996, leaving a vast body of intellectual and literary work as his legacy.
This guide will summarize the key ideas in Cosmos in three parts:
- In Part 1, we’ll summarize Sagan’s description of the evolution of life on Earth, and his thoughts about the possibility that a similar evolution could occur elsewhere, based on what we know about the universe.
- In Part 2, we’ll look at the history of humanity’s inquiry into the cosmos, outlining the astronomical discoveries made by important scientific figures.
- In Part 3, we’ll delve into Sagan’s theories about the possibility for interstellar travel, and the search for extraterrestrial life.
As this book was published in 1980, we’ll update the information with the scientific discoveries made since that time, as well as provide perspectives from other experts in related fields.
Part 1: The Vastness of Space and Time
In this section, we’ll discuss Sagan’s description of the vastness of the cosmos (or universe), and our place in it. We’ll begin by examining how life evolved on Earth to find our place within that timeline. After situating ourselves, we’ll zoom out to look at Sagan’s bigger picture of where Earth fits into the timeline and space of the universe. Ultimately, when we look at what’s known about the cosmos, we’ll discover that in the grand scheme of things, we’re pretty insignificant.
Humanity’s Place on Earth
Sagan begins the story of humanity’s history by teaching us that all life is made of carbon-based organic molecules, but there was once a time on Earth without life. How was it possible for life to come from non-life? Let’s look at a timeline of how that process occurred and discuss Sagan’s thoughts on whether the same thing could occur on other planets.
About 4.6 billion years ago, the Earth formed out of condensed gas and dust. The fossil record tells us life arose about 4 billion years ago, meaning that for 600 million years there was no life on Earth. According to Sagan, hydrogen-based molecules that are found throughout space were gradually broken down by the sun’s energy, and they formed into other more complex molecules—from one-celled plants to multicellular organisms. Sagan says that scientists have been able to replicate this on a much smaller scale in the laboratory. Scientists can create organic molecules that may have the potential to evolve into more complex life forms by exposing common inorganic gas molecules to an energy source, such as ultraviolet light. So, Sagan says, we know it’s possible to create living molecules from simple non-living gasses.
Creating Life from Non-Life
The process of life arising from non-living matter is called “abiogenesis.” The question of whether this is possible is still debated among scientists, even though some research has shown evidence that it could be possible. In 2018, scientists were able to create synthetic cell-like structures that have the potential to divide and replicate on their own, essentially becoming “alive.” This research could give clues to what kinds of life might possibly evolve on other planets, as well as raising philosophical questions about what defines “life.”
About 1 billion years ago, simple plants had evolved. Sagan tells us that for about 3 of the 4 billion years of life on Earth, the dominant life form was blue-green algae that covered the oceans. Those plants gradually changed the atmosphere by generating oxygen, allowing for many types of organisms to arise and others to die off. The process of evolution by natural selection gradually shaped these simple organisms into all of the life forms we know today.
About 10 million years ago, early hominids appeared, according to Sagan, with modern humans emerging only about 300,000 years ago. This means humans have existed for approximately .007% of the Earth’s history.
Evolution Is a Fact
Although it’s still a topic debated between science and religion, Sagan says evolution “is a fact, not a theory.” In fact, with species that have very short lifespans, evolution by natural selection is observable in real time.
For example, one of the early experiments that gave credibility to the theory, the case of the peppered moth, has been confirmed by modern science. During the Industrial Revolution, scientists noticed that the normally pale-colored moth had turned darker to camouflage itself against soot-covered surfaces. This was a result of the individuals who were darker in color surviving predators and passing on the more melanated pigment to their offspring. Over generations, the peppered moth as a species had darkened. Later, after clean-air policies had been put into place and the soot began to subside, the peppered moths began turning lighter in color again, to match the lichen on the trees they live on.
Evolution on Other Planets
Could life have evolved similarly on other planets? Sagan says it’s certainly possible. The gasses from which the first living molecules formed exist everywhere in the universe. However, for 3 billion years, life on Earth never evolved past blue-green algae, so Sagan points out that evolving large complex life forms is much harder than the origin of life itself. Therefore, he says that if there is life on other planets, it’s more likely to be simple organisms, because the time required to evolve complex intelligent life means that, statistically, the majority of life in the universe would be in some stage of evolution preceding the complex life form stage.
However, it’s certainly possible that there are some planets on which life has been evolving as long as it has been on Earth, or even much longer. Sagan speculates that life forms that have evolved much longer than humans may become extinct (for various reasons including self-destruction, which he argues is happening with humans), leaving only a relatively small time window, on the cosmic scale of time, for multiple forms of complex, intelligent life to exist simultaneously.
The Probability of Intelligent Life
The probability for how many intelligent life forms exist in the universe has been calculated using what’s called the Drake Equation. While it can only be estimated, not effectively “solved,” the Drake Equation suggests the number of intelligent life forms existing in the universe could be as high as several million, and as low as one. It might just be us.
In The Sixth Extinction, Elizabeth Kolbert describes the evolutionary timeline of life on Earth as a series of long phases of stability, alternating with rapid calamitous changes. These calamities (including drastic climate shifts and asteroids) have caused five periods of mass extinction, each resulting in the disappearance of around 75-95% of the species on Earth. Kolbert argues that the sixth era of mass extinction is underway, caused by the environmental effects of human activities.
It’s possible that in this wave, humans could be one of the species to become extinct, and of all the species that have evolved on Earth, we’re the only one that has evolved the intelligence to be able to communicate with extraterrestrial beings. Because of our risk of extinction, even if another intelligent life form arises, the chance that we’ll both exist and have the capabilities to communicate with one another at the same time is slim.
Sagan also points out that life elsewhere in the cosmos is probably nothing like we imagine, because our imaginations are limited by what we know. Given the many possibilities in the way molecules can combine, along with the vast possibilities for how characteristics could evolve, Sagan says that any life that has evolved elsewhere would most likely be out of our realm of imagination.
(Shortform note: Astronomer and “space artist” David Aguilar created a children’s book for National Geographic, depicting some possibilities for what extraterrestrial life could look like. While nobody can really know the answer to this, what’s unique about Aguilar’s depictions is that he used scientific knowledge about the atmospheres and environments such beings would need to adapt to, in order to imagine what kinds of features they might have.)
Earth’s Place in the Universe
While Earth seems special and central to our perspective, from the cosmic perspective it’s a minuscule piece of rock floating in a vast universe. To begin to understand just how vast the universe is, Sagan explains that distances between the celestial objects are so huge that we measure them in speed of light units. Light travels 6 trillion miles (10 trillion km) in one year, and a little over 11 million miles (18 million km) in one second. Earth is 8 light-minutes away from the sun. (Shortform note: to put it in perspective, the known universe—the distance we can measure—is about 94 billion light years across.)
So, to understand our place in the universe as Sagan describes it, we’ll begin with Earth and zoom out. The Earth and our eight planet neighbors all orbit the sun, due to its gravitational pull. This is called our solar system. (Shortform note: to get an idea of the size of our solar system, Pluto, the furthest planet from the sun, is about 3.7 billion miles from the sun).
Zooming out further from our own solar system, Sagan tells us that the sun is a relatively ordinary star that resides toward the outer reaches of the Milky Way galaxy. A galaxy is an enormous cluster of stars, all linked together by gravity. A typical galaxy has an average of about 100 billion stars, Sagan says, and the cosmos includes about 100 billion galaxies. (Shortform note: Some astronomers now estimate that there may be about 2 trillion galaxies in the universe.)
Our own galaxy, the Milky Way, is relatively large, containing about 400 billion stars. Sagan says that the majority of those stars could potentially have satellites (planets) revolving around them, as does our sun. He says that evidence would suggest that most probably do, which suggests hundreds of billions of potential planets in just our galaxy alone, not to mention the other 100 billion known galaxies.
(Shortform note: This image depicts the spiral-shaped Milky Way galaxy. Notice the line pointing to the location of the “neighborhood” of our solar system. At this scale the individual features of our solar system itself would be far too small to see.)
If these numbers convey how vast the matter of the universe is, Sagan goes on to point out that despite the staggering number of stars and other orbiting objects in the universe, it actually consists of far more empty space than matter.
All of this considered, Sagan argues that we must conclude that we’re not that significant in the grand scheme of things. Not only is Earth’s place in the universe insignificant, but we humans are only one of innumerable possible forms of life, and even among the diverse life forms on Earth, we’re descended from blue-green algae, just like everything else. Sagan says that there’s no scientific justification for claiming that our place or position in the world is unique or special relative to anything else.
Despite this, he points out that many scientists have been persecuted and ostracized for making such claims. Next we’ll discuss some examples of those who have challenged the perspective of Earth-centered and human-centered privilege.
A Pale Blue Dot
Sagan continues to emphasize humanity’s insignificance in his later book, Pale Blue Dot (published in 1994). The title was inspired by a photo of Earth taken by the Voyager I spacecraft from about 4 billion miles away. In that photo, the Earth appears as a tiny pinpoint in a vast dark sky. Sagan comments in Pale Blue Dot that it’s humbling to remember how insignificant we are, and this should help us recognize the folly of our pursuits for power and delusions of superiority.
He says: “The Earth is a very small stage in a vast cosmic arena. Think of the rivers of blood spilled by all those generals and emperors so that, in glory and triumph, they could become the momentary masters of a fraction of a dot.”
Part 2: History of Astronomical Thought
Humans in all places and times have been fascinated by the skies. We’ve used the stars to guide us, to mark the passage of seasons, and make sense of our place in the world for as long as we’ve existed. But our understanding of the nature and order of the universe, and our place in it, has evolved substantially over time. Sagan gives a historical picture of how humanity developed its beliefs “from chaos to cosmos.”
In this section, we’ll briefly outline the Western history of astronomical discovery, as presented by Sagan, from Thales of Miletus in ancient Ionia, to Isaac Newton in 17th-century England.
The Ionian Awakening
Sagan’s history begins between 600 and 400 BC, when a revolution of scientific thought occurred in Ionia, a Greek settlement on the Aegean coast in what is now Turkey. Ionia is often considered the birthplace of science, in the Western tradition. This revolution was sparked by a scientist named Thales of Miletus, who Sagan says was the first known scientist bold enough to attempt to explain the world without appealing to the supernatural. He explains that this had far-reaching consequences, as it prompted a shift from a world made by gods to a world made by natural processes.
The Natural and the Supernatural
Naturalism is the philosophical theory that everything in the world is natural and can be understood scientifically without supernatural explanations. Thales of Miletus is often considered the “grandfather of naturalism.” Other ancient Greeks adopted this approach to the world as well, though some of them, including Thales, still conceived of the natural world as possessing mystical qualities, or having an underlying mind-like intelligence.
However, others, like Democritus, rejected ideas of any intelligence or spiritual essence in nature. He and others in this school of thought, called atomists, conceived of the natural world as strictly material and inanimate, and operating on mechanistic principles (this falls into the category of a materialist worldview). Over the next 2,000 years we see a history of debate and tension between this worldview and one that invokes a supernatural creator.
In recent history, scientists in fields like biology and ecology are coming to a consensus that the natural world is indeed imbued with intelligence. Animals, plants, and even bacteria are now known to learn, remember, and communicate in ways we were previously unaware of. While none of this implies a supernatural creator, it certainly implies something other than the cold, mechanistic view of strict materialism.
Sagan details the revolutionary discoveries made during this time, including the idea that the sun was the center of the universe (heliocentric), rather than the Earth (geocentric). Copernicus is often given credit for the heliocentric model of the universe. However, Sagan says that Aristarchus is the first person known to have proposed that the Earth revolves around the sun, in Ionia, in 280 BC, 1800 years before Copernicus. Therefore, he points out that Galileo described Copernicus as “restorer and confirmer” of this worldview, not the originator of it.
Scientists in this period also proposed that the orbits of the planets were elliptical rather than circular, and that gravitational forces were at work in their orbiting of the sun.
(Shortform note: Sagan takes a Western historical perspective in the timeline he presents. In fact, the earliest known suggestion that the Earth revolves around the sun comes from an ancient Vedic text from India. An Indian astronomer named Yajnavalkya, proposed the heliocentric model of the universe around 800 BC, more than 500 years before Aristarchus. In that text, he states, “The sun strings these worlds—the earth, the planets, the atmosphere—to himself on a thread.” It’s unclear why Sagan doesn’t acknowledge this, which leaves us to question whether it’s because of a bias toward Western history or if he was unaware (or skeptical) of this text.)
According to Sagan, Aristarchus’ “great legacy” is the argument that we’re not special. He argued that humans are not the center of the universe, nor is our planet. This idea can be extended to many aspects of life—Aristarchus challenged the prevailing anthropocentric (“human-centered”) worldview. Sagan explains that this was a bold challenge to the social order, as it conflicted with a religious worldview that asserted that humans are uniquely created by the Gods, as well as with the idea of natural social hierarchies.
(Shortform note: Challenging an anthropocentric worldview isn’t necessarily in contradiction with all religions. Most indigenous religions are animistic belief systems that see humans as a part of the natural world just like everything else. These belief systems don’t assume humans are superior to, or have dominion over, anything else in nature, and put a strong emphasis on respect and honor for all non-human beings.)
Alexandria
By the 3rd century AD Alexandria, Egypt had become the new center of scientific inquiry in the West. Around 285 BC, the Great Library of Alexandria was established as the world’s greatest repository of scientific knowledge and literature, though Sagan laments that most of the documents were lost when it was destroyed. He says that he has often wondered where we might be today (scientifically) if all of that knowledge hadn’t been lost.
(Shortform note: The Great Library of Alexandria is believed to have contained in its collections over half a million written works on every subject of human knowledge and inquiry, from cultures across the world. Some scholars believe the Library was burned to the ground in 48 BC during Julius Caesar’s occupation of Alexandria, while others believe it suffered a more gradual destruction due to long periods of political unrest in the area. There is evidence that the buildings were converted into churches and mosques at different periods. Whatever the case, the vast majority of the Library’s contents have been lost to history.)
Sagan explains that it was in Alexandria that Eratosthenes (276-194 BC) made the discovery that the Earth was round. And although this was resisted by many at the time, he points out that it was crucial knowledge for an accurate scientific understanding of how the celestial bodies operate, as well as solidifying a view of Earth as one among other spherical celestial bodies. This also paved the way for explorers who would brave the circumnavigation of the globe centuries later.
However, Sagan explains that much of the astronomical theory coming out of this time period was rejected in favor of the more-accepted Ptolemaic worldview. Ptolemy (100-170 AD), maintained that the Earth was the center of the universe, and the sun, moon, other planets, and stars moved around it, attached to invisible spheres. This model, Sagan says, was ultimately supported by the Church in the coming centuries, and because of that institution’s powerful reach, the Ptolemaic model lingered through the Middle Ages.
Astronomy During the Middle Ages
Sagan’s timeline skips from around the time of Ptolemy to the 16th century. The large gap in history is often attributed to the suppression of science in the Western world by the Roman Catholic Church throughout the Middle Ages (5th-15th centuries).
However, there’s ample documentation of important astronomical research during this historical period, especially in the Islamic world. Islamic scholars were particularly interested in accurate astronomical explanations because the Qur’an instructs Muslims to pray five times a day facing toward the city of Mecca (the birthplace of Muhammad), as well as giving instructions for fasting that require knowing the exact times of sunrise and sunset.
European Renaissance
When Europe began to emerge from what is known as the Dark Ages, the astronomical models we know to be correct today were developed. Here we’ll look at a brief timeline of discovery, as presented by Sagan, during the 16th and 17th centuries in Europe.
(Shortform note: The concept of the “Dark Ages” came from Renaissance-era scholars who believed ancient Greece was the pinnacle, up to that point, of human intellectual achievement, and that the subsequent historical era dominated by the Church in Europe was antithetical to progress. Sagan’s timeline in Cosmos contributed to solidifying this view in the popular imagination of the late 20th century. However, although it’s clear that the Church had a negative impact on scientific research, most scholars don’t use the term “Dark Ages” anymore, and consider the concept itself to be a “myth.”)
In 1543, Polish mathematician and astronomer Nicolaus Copernicus proposed his heliocentric model. In 1616 the Catholic Church placed Copernicus’ work on their banned books list, where it remained until 1835.
In 1571, German astronomer Johannes Kepler also came out in support of the Copernican heliocentric model. According to Sagan, Kepler was a religious man, but he thought a heliocentric model was more in line with religious beliefs. In his view, the sun was a metaphor for God, around which everything revolves. Sagan says that Kepler also calculated the elliptical orbits of the planets to explain their previously unexplainable movements. Because of these theories, Kepler was excommunicated by the Lutheran Church.
In the late 1500s, Italian astronomer Galileo Galilei made advancements to the existing telescope technology. Due to his more powerful designs, he was able to discover the four largest moons of Jupiter, and the craters of the moon. Galileo also adhered to the heliocentric model.
(Shortform note: In 1633 Galileo was investigated and tried by the Roman Inquisition, charged with heresy, forced to recant, and spent the last decade of his life on house arrest. While in there, however, he wrote some of his most important work.)
In the 1600s, Isaac Newton discovered the law of gravity, which Sagan tells us was able to solidify the explanation of how the planets revolve around the sun, and the moons around the planets. Sagan says that Newton’s discoveries and the laws of nature derived from them, laid the foundation for our current understanding of the universe.
Absence of Evidence Is Not Evidence of Absence
Sagan points out that it was actually quite rational to believe that the Earth is flat and that the sun revolves around us, because from our perspectives that’s exactly how it appears. The idea that the Earth is round, rotating, and orbiting the sun is contrary to what our sense perceptions tell us. So, even setting religious beliefs aside, it’s natural that humans strongly resisted these ideas for a long time, especially in the absence of the kind of technology we have now—for example, satellite photos.
This stresses the importance, though, of not conflating “absence of evidence” with “evidence of absence.” In other words, being unable to prove something exists is not the same as being able to prove it doesn’t exist. It was only the unrelenting persistence of these scientists in their attempts to explain why the planets moved irregularly relative to the stars that led to their revolutionary discoveries.
Part 3: Exploration of Space
Now that we have a solid working model of the universe, and have been able to directly observe much of it via telescopes, we move into the age of physical exploration. We’ll begin with discussing what modern astronomers have discovered about the celestial bodies in our own solar system, then look at the potential that lies beyond our solar system. Sagan offers some insightful views on the potential for interstellar travel and for discovery of life on other worlds.
Our Solar System
On July 20th, 1969, humans made the first trip to a destination off the planet Earth and set foot on the moon. The moon is the nearest celestial body to us, and it remains the only one humans have ever traveled to. However, Sagan explains that we’ve been able to create vehicles that can travel much further, enduring the inhospitable climates elsewhere in the solar system, and send information to us.
At present, Sagan says that none of the atmospheres and climates of the other bodies in our own solar system are inhabitable by anything like the kind of life we have here on Earth. But he reminds us that life could take any number of forms, and because it would have evolved in a different atmosphere than ours, it could take forms that we might not expect.
(Shortform note: Astronomers now believe that Venus may have once had an atmosphere more like Earth’s, but that greenhouse gasses accumulated and eventually made it the volcanic inferno it is now. Venus is the hottest planet in our solar system, with a surface hot enough to melt lead. Its previous oceans were boiled away, and its atmosphere became dense carbon dioxide, with sulfuric clouds. Astrobiologist Vikki Meadows believes it’s an example of an alternate planetary evolution that could serve as a warning for Earth about “how terrestrial planets die.”)
Looking for Life on Mars
So far, Sagan explains, we’ve been able to fairly extensively study the Moon, Mars, Venus, Jupiter and its moons, and Saturn and its moons. Sagan says that Mars has been the primary focus of study because its polar caps are covered with ice—which means there’s the possibility that it was once liquid water, which in turn denotes the possibility for life.
(Shortform note: In 2016, NASA’s Mars Reconnaissance Orbiter provided images that astronomers believe suggest liquid water is presently flowing on the surface of Mars. They believe the water would be briny, containing high levels of salt, which would allow it to remain liquid in otherwise freezing temperatures. Other scientists have contested this evidence, arguing that the features are more likely created by sand.)
As of the writing of this book, Sagan says that no compelling evidence for life has been found on Mars. However, he says we’ve been able to map the entire planet with orbiting satellites, and the US’s Viking lander has successfully landed on its surface and collected and tested soil samples. While some of the microbiology tests showed promise of chemical reaction, Sagan says there was no definitive evidence of the kind of life we know.
(Shortform note: The Curiosity rover landed on Mars in 2012 and is still exploring the planet as of 2022. The major mission of Curiosity is to discover whether Mars may have once had the right environmental conditions to support simple life forms. In 2022, it returned data from an analysis of rock samples that contain a form of carbon associated with biological life. Scientists say they would still need more evidence to support a claim that there was once life on Mars, but the finding is compelling.)
Sagan speculates on what we should do if we did discover any form of life on Mars. He strongly feels that if we discover even the smallest microbial life we should leave Mars alone entirely, and do nothing more to interfere with it. However, he says if we conclude that there is no life on Mars, he can imagine possibilities for humans to colonize and settle there, after altering the atmosphere.
Mission to Mars
One of the major contemporary proponents of colonizing Mars is entrepreneur and investor Elon Musk. Musk founded the private spaceflight company SpaceX, which is developing a rocket called Starship that would be able to transport humans to Mars. Musk imagines colonization of Mars to be essentially a “life insurance” policy in the face of potential catastrophic events on Earth. His vision includes a process of “terraforming” the planet to make the atmosphere more suitable for human habitation, similar to Sagan’s suggestion, but in the shorter term it would have to involve living in an encapsulated artificial environment.
Although tests have been conducted on prototypes of Starship, the cost of a mission to Mars may be a prohibitive factor. However, NASA has said that they envision a crewed mission to Mars by around 2040.
The Space Probes
Spacecraft called Voyager I and II were designed to explore beyond our immediate neighbors. Launched in 1977, their mission was to fly beyond Mars, travel among the moons of Jupiter and Saturn, and then ultimately drift off into interstellar space forever.
(Shortform Note: This website shows the current locations of Voyager I and II, 44 years after their launch. Voyager II went on to explore Uranus and Neptune, and it’s still the only spacecraft to have visited those outer planets. They’ve both now flown beyond the solar system, into interstellar space, and are still in operation.)
Sagan tells us that Voyager I took pictures of three of Jupiter’s four largest moons, and Voyager II was able to capture photos of the fourth one, Europa. Europa is unique, he says, in that there are visible geometric lines on its surface that look like nothing else we know of, other than man-made canals. (Shortform note: See a video and photo of Europa here.)
Another one of Jupiter’s moons, Io, is unique in that the Voyager images show active volcanoes over much of its colorful surface. Sagan says this appears to be a newer planet still actively forming, with a rapidly changing landscape. (Shortform note: See a photo and more in-depth description of Io here.)
Beyond Our Solar System
Even with the ability for travel within our solar system being limited, Sagan points out that humans still dream of going further, and he thinks we always will. Since we haven’t found any evidence of a habitable environment within our solar system, might there be some in other solar systems?
We don’t know how many planetary systems might exist in the cosmos. Sagan says the evidence suggests that almost all single stars like the sun should have satellite planets, but we can’t see them because the light of the stars is too bright. He says scientists are working on telescope technology that could dim the light so they might be able to see the much smaller objects orbiting the stars. Also, he says that in addition to “planets” orbiting stars, Jupiter, Saturn, and Uranus all have satellite “moons” that are planet-like, so many other planets could have such satellites as well. So there are innumerable possibilities for other worlds that could sustain life.
Discovery of Exoplanets
The technology that’s needed to observe exoplanets (planets orbiting stars outside of our solar system) now exists. The first exoplanet was observed in 1995, orbiting a star called Pegasus 51, about 50 light-years away from Earth. Since then, astronomers have discovered at least 4,000 more exoplanets in the Milky Way galaxy. Astrophysicist Hakeem Oluseyi says that the more scientists discover about the universe, the more likely they believe it is that life exists elsewhere. Scientists now estimate that there are about 2 trillion galaxies in the universe; Oluseyi believes this makes the odds very high that there is intelligent life out there somewhere. However, he still thinks we’re a very long way away from being able to travel or even communicate across this kind of distance.
Interstellar Travel
Alpha Centauri is the closest “star” to us, being 4.3 light-years away, but Sagan explains that it’s actually a triple star system. Considering the vast distance, will it ever be possible to travel to other solar systems? Sagan suggests that nuclear fusion technology might make it possible to power spacecraft fast enough. However, he explains that such technology would require the spacecraft to be launched from Earth’s orbit, rather than from land, because of the dangers involved with the nuclear fusion reaction.
Nuclear Fusion Technology
In 2022, a panel of experts speaking at a meeting of the International Atomic Energy Agency discussed how advancements in nuclear fusion technology could soon be used to propel faster space travel. They say that rockets would have to lift off from earth using traditional fuel, but then once in space, the nuclear power could take over, and the technology currently available could cut travel time to Mars by 25%. Currently it takes about 7 months to reach Mars.
Additionally, this nuclear technology could be used as a sustainable power source for extraterrestrial settlements, should we have the ability to create a long-term human habitation on Mars or another planet. Potentially, this kind of technology could power such a station for decades.
Sagan says the technology to build a ship that can travel anywhere close to light-speed is probably thousands of years away, but a ship using nuclear fusion technology may be able to travel about 10% the speed of light. With Alpha Centauri being 4.3 light-years away, a voyage there would take 43 years, meaning it would be feasible for humans to travel there within a lifetime. But he proposes that to travel any further, we might need “multigenerational” spacecraft, where generations of humans would be born and live their lives, so that subsequent generations might reach other solar systems.
Considering the scientific discoveries being made in Ionia over 2,000 years ago, Sagan believes that we might be there right now if that scientific inquiry had not been suppressed by religious forces for centuries.
Generation Ships
The hypothetical concept of multigenerational space travel is something astronomers have pondered for decades, and some have undertaken serious research into the idea. They call such a vehicle a “generation ship.” A 2019 article by an international team of scientists addressed some of the practical questions concerning the development of a generation ship, such as how many people it would require, how large the ship would need to be, and how food would be produced.
They determined that such an endeavor would require a crew of at least 98 people, to avoid genetic issues with inbreeding; they suggested around 500 people optimally. Based on a proposed cylindrical shape, they said the ship would need to be around 1,050 feet long and 735 feet in radius, which they point out is still smaller than the world’s largest building.
The experts also devised a plan for food involving cultivation in an artificially created plot of land that would need to be about 0.17 square mile in size. The only practical issue they haven’t yet worked out is how to have sufficient water. But, when that’s solved, they say the idea is quite feasible—given an adequate budget, which would need to be enormous.
The Search for Extraterrestrial Life
The idea of intelligent life existing on other planets is probably the most powerful driving force of humanity’s exploration of the cosmos. It’s the theme of countless works of human imagination, from books and poetry to movies and television. Sagan believes the evidence would suggest it’s far more likely than not that there’s some kind of life out there in the universe; he says there could realistically be a hundred billion planetary systems in the galaxy, and each and every one of them would be unique.
According to Sagan, the same kind of evolutionary process that happened on Earth should logically operate everywhere in the universe. But with the number of possibilities of how that would unfold in a hundred billion unique environments, he thinks any life that may have evolved would probably be nothing like humans, or any kind of life we know.
(Shortform note: Carl Sagan’s 1985 novel Contact, which was used as the basis for a movie of the same name in 1997, explores this question. In one scene, a character asks another “Do you think there are people on other planets?” to which the reply is, “The universe is a pretty big place…so if it’s just us, seems like an awful waste of space.” While Sagan makes it clear that he doesn’t think life on other planets would be “people,” like us, this sentiment clearly reflects his own thoughts about the potential.)
Scientists have been intentionally trying to communicate with other potential life in the universe since the 1970s. Sagan says that we have the technology to communicate over interstellar distances; it’s called radio astronomy. Radio waves travel at the speed of light. The Arecibo Observatory in Puerto Rico has been searching continuously for any radio waves coming from outer space, and Sagan says that it once broadcast a message into space, directed toward a distant star cluster called M13.
Sending Messages to the Stars
That first interstellar message was broadcast in 1974 and contained binary-coded information, including a description of DNA and graphics of a stick-figure person, our solar system, and the telescope that sent the message. Several other messages in different forms have been sent since that time.
The Arecibo telescope collapsed in 2020. In 2022, astronomers created an updated message that they’ve proposed to send out later in the year via two radio telescopes—one in China and one in northern California. That message includes a more sophisticated drawing of humans, a number of mathematical operations, a description of the Earth, and a detailed stellar map that shows the location of Earth—that last portion is controversial, as many believe it’s risky to broadcast our location without any idea of what/who might receive it.
Humans have created many imagined scenarios in film and literature depicting the arrival of alien life on Earth. In pondering this possibility, Sagan says that one thing is clear: There’s no cause to worry about what we would do if extraterrestrial beings arrived here on Earth. Because if that happened, they’d be so technologically beyond us that there would be nothing we could do. He also hypothesizes that any species that has survived long enough to develop such technology has probably learned how to live effectively and peacefully with themselves and others, or they would have destroyed themselves already, as humans may be in danger of doing.
Breakthrough Listen
Physicist Stephen Hawking was both an enthusiastic supporter of searching for extraterrestrial life and very cautious about the idea of actually making contact. In 2015, Hawking helped to launch Breakthrough Listen, the most comprehensive program ever undertaken to explore interstellar space for messages or signs of life. The project aims to survey the 1 million closest stars to Earth, using radio and optical telescope technology.
On the question of what we should do if we discover signs of life, Hawking advocated for quietly collecting as much information as possible, without revealing ourselves. He didn’t necessarily agree with Sagan’s sentiment about how extraterrestrials might approach us. He thought an extraterrestrial visit to Earth would likely have the same result for us that European colonization of the Americas had on the Native peoples. He said “we only have to look at ourselves to see how intelligent life might develop into something we wouldn’t want to meet.”